Sending cross-chain authenticatable messages

ABSTRACT

Disclosed herein are computer-implemented methods; computer-implemented systems; and non-transitory, computer-readable media, for sending cross-chain messages. One computer-implemented method includes storing an authenticable message (AM) associated with a first account to a blockchain associated with the first blockchain network, where the AM is generated based on a protocol stack comprising an outer-layer protocol, a middle-layer protocol, and an inner-layer protocol, the outer-layer protocol comprises an identifier (ID) of an originating blockchain network and the middle-layer protocol, the middle-layer protocol comprises information of the sending account and the inner-layer protocol, the inner-layer protocol comprises an ID of a destination blockchain network, information of a receiving account associated with the destination blockchain network, and message content. The AM and location information is transmitted to a relay to be forwarded to the second account associated with the second blockchain network.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of PCT Application No. PCT/CN2020/071574, filed on Jan. 11, 2020, which claims priority to Chinese Patent Application No. 201910579567.1, filed on Jun. 28, 2019, and each application is hereby incorporated by reference in its entirety.

TECHNICAL FIELD

Implementations of the present specification relate to the field of blockchain technologies, and more specifically, to a method and a device for sending a cross-chain authenticatable message.

BACKGROUND

A blockchain technology, also known as a distributed ledger technology, is a decentralized or distributed database technology. The blockchain technology has features such as decentralization, openness and transparency, tamper-resistance, and trustworthiness. Data in a blockchain network is broadcast to blockchain nodes in an entire network, each blockchain node has complete and consistent data. As the blockchain technology becomes increasingly popular, different types of blockchain networks have emerged and have been applied to fields such as finance, healthcare, supply blockchain network, asset management, and backtracing. However, most of applications on the blockchain network (cryptocurrency or smart contract) cannot be applied beyond the boundary of a particular blockchain network, and cannot cooperate with other blockchain networks to implement value exchanges, which affects functions of the blockchain network. How to enable different types of blockchain networks to cooperate to implement value exchange has become a direction of exploration. Currently, many cross-chain technologies have emerged. However, different cross-chain technologies have different unique designs and are applied to different scenarios. For different cross-chain scenarios, one blockchain network may need to be connected to various cross-chain platforms.

As such, a more effective cross-chain information transfer solution is needed.

SUMMARY

Implementations of the present specification are intended to provide a solution for more effective transfer of a cross-chain authenticatable message, to alleviate disadvantages in the existing technology.

To achieve the previous objective, an aspect of the present specification provides a method for sending a cross-chain authenticatable message, where sending a cross-chain authenticatable message refers to sending the authenticatable message from a first account in a first blockchain network to another blockchain network, the first blockchain network is connected to the relay, the relay is further connected to at least one of other blockchain networks, the at least one of other blockchain networks includes a second blockchain network, and the method is performed by the first blockchain network and includes: storing first data through consensus into the first blockchain network by using the first account, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and providing the first data and first location information to the relay, to provide the authenticatable message to the second account in the second blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

In an implementation, storing first data through consensus into the first blockchain network by using the first account includes: storing the first data into the first blockchain network by invoking a first smart contract by using the first account, where at least the following parameters are input to the first smart contract when the first smart contract is invoked by using the first account: an identifier of the second blockchain network, a second account, and message content.

In an implementation, the first data is labeled with a pre-determined label.

In an implementation, the first data is a receipt, and the receipt includes a log generated after the first smart contract is executed, and a data field of the log is the authenticatable message.

In an implementation, the first data is labeled with a pre-determined label, and the pre-determined label is the pre-determined topic.

In an implementation, the pre-determined label is an account identifier of the first smart contract.

In an implementation, the first-layer protocol further includes a protocol version number field and a reserved field.

In an implementation, the second-layer protocol further includes a type field used to indicate a usage scenario type of the authenticatable message.

In an implementation, the type is any one of the following types: message type, remote procedure call type, and issuance/subscription type.

In an implementation, the third-layer protocol further includes a sequence number field used to indicate a current sending sequence number when the authenticatable message is sent to the second account for a plurality of times by using the first account.

In an implementation, the first account is a contract account of a second smart contract.

Another aspect of the present specification provides a method for transferring cross-chain authenticable message, where the method is performed by a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and the method includes: obtaining the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network; and sending, based on the identifier of the second blockchain network in the authenticatable message, the first data and the first location information to the second blockchain network.

In an implementation, the first data is labeled with a pre-determined label, and obtaining the first data and first location information from the first blockchain network includes obtaining the first data and the first location information from the first blockchain network based on the pre-determined label.

Another aspect of the present specification provides a method for receiving a cross-chain authenticable message, where receiving a cross-chain authenticable message refers to receiving the authenticatable message from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, the second blockchain network includes at least one second data related to at least another blockchain networks synchronized through the relay, where the at least another blockchain network includes a first blockchain network, and the method is performed by the second blockchain network, including: receiving first data and first location information from the relay, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account, and the first location information indicates a location of the first data in the first blockchain network; obtaining, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network; verifying the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information; and after the verification succeeds, providing the authenticatable message to the second account based on the second account in the authenticatable message.

In an implementation, the first data is a first receipt in a first block in the first blockchain network, the first location information includes a block number of the first block and a receipt number of the first receipt in the first block, the second data related to the first blockchain network includes a block head of each block in the first blockchain network, and verifying the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information includes: using a simplified payment verification method to verify, based on the first receipt, the block head of each block, and a Merkle tree path that is associated with the first receipt and that is included in the first block, that the first receipt is received from the first block in the first blockchain network, where the Merkle tree path is obtained based on the first location information.

In an implementation, the authenticatable message is included in a first log of the first receipt, and verifying the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information further includes: verifying, based on a sending field in the first log, that the first account is an account used to send the authenticatable message.

In an implementation, the second account is a contract account of a third smart contract, and providing the authenticatable message to the second account includes: invoking the third smart contract by using the authenticatable message as an input parameter, to provide the authenticatable message to the second account.

Another aspect of the present specification provides a method for relaying a cross-chain authenticatable message, where the method is performed by a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and the method includes: obtaining the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network; and obtaining, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network; verifying the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information; when the verification succeeds, adding a digital signature on the authenticatable message; and sending, based on the identifier of the second blockchain network in the authenticatable message, the first data and the digital signature of the first data to the second blockchain network.

Another aspect of the present specification provides a method for receiving a cross-chain authenticatable message, where receiving a cross-chain authenticatable message refers to receiving the authenticatable message from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, the relay is further connected to at least one of other blockchain networks, the at least one of other blockchain networks includes a first blockchain network, the second blockchain network pre-stores a public key of the relay, and the method is performed by the second blockchain network and includes: receiving the authenticatable message and the digital signature of the authenticatable message from the relay, where the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; verifying the digital signature by using the public key of the relay; and after the verification succeeds, providing the authenticatable message to the second account based on the second account in the authenticatable message.

Another aspect of the present specification provides a device for sending a cross-chain authenticatable message, where sending a cross-chain authenticatable message refers to sending the authenticatable message from a first account in a first blockchain network to another blockchain network, the first blockchain network is connected to the relay, the relay is further connected to at least one of other blockchain networks, the at least one of other blockchain networks includes a second blockchain network and the device is disposed in the first blockchain network and includes: a storing unit, configured to store first data through consensus into the first blockchain network by using the first account, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and a providing unit, configured to provide the first data and first location information to the relay, to provide the authenticatable message to the second account in the second blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

In an implementation, the storing unit is further configured to store the first data into the first blockchain network by invoking a first smart contract by using the first account, where at least the following parameters are input to the first smart contract when the first smart contract is invoking by the first account: the identifier of the second blockchain network, the second account, and message content.

Another aspect of the present specification provides a device for relaying a cross-chain authenticatable message, where the device is disposed at a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and the device includes: a query unit, configured to obtain the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network; and a sending unit, configured to send, based on the identifier of the second blockchain network in the authenticatable message, the first data and the first location information to the second blockchain network.

In an implementation, the first data is labeled with a pre-determined label, and the acquisition unit is further configured to obtain the first data and the first location information from the first blockchain network based on the pre-determined label.

Another aspect of the present specification provides a device for receiving a cross-chain authenticatable message, where receiving a cross-chain authenticatable message refers to receiving the authenticatable message from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, at least one piece of second data that is related to at least one of other blockchain networks is synchronized to the second blockchain network by using the relay, the at least one of other blockchain networks includes a first blockchain network, and the device is deployed in the second blockchain network and includes: a receiving unit, configured to receive first data and first location information from the relay, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account, and the first location information indicates a location of the first data in the first blockchain network; an acquisition unit, configured to obtain, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network; a verification unit, configured to verify the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information; and a providing unit, configured to: after the verification succeeds, provide the authenticatable message to the second account based on the second account in the authenticatable message.

In an implementation, the first data is a first receipt in a first block in the first blockchain network, the first location information includes a block number of the first block and a receipt number of the first receipt in the first block, the second data related to the first blockchain network includes a block head of each block in the first blockchain network, and the verification unit is further configured to use a simplified payment verification method to verify, based on the first receipt, the block head of each block, and a Merkle tree path that is associated with the first receipt and that is included in the first block, that the first receipt is received from the first block in the first blockchain network, where the Merkle tree path is obtained based on the first location information.

In an implementation, the authenticatable message is included in a first log of the first receipt, and the verification unit is further configured to verify, based on a sending field in the first log, that the first account is an account used to send the authenticatable message.

In an implementation, the second account is a contract account of a third smart contract, and the providing unit is further configured to invoke the third smart contract by using the authenticatable message as an input parameter, to provide the authenticatable message to the second account.

Another aspect of the present specification provides a device for relaying a cross-chain authenticatable message, where the device is disposed at a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and the device includes: a query unit, configured to obtain the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network; and an acquisition unit, configured to obtain, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network; a verification unit, configured to verify the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information; and a signing unit, configured to: when the verification succeeds, add a digital signature on the authenticatable message; and a sending unit, configured to send, based on the identifier of the second blockchain network in the authenticatable message, the first data and a digital signature of the first data to the second blockchain network.

Another aspect of the present specification provides a device for receiving a cross-chain authenticatable message, where receiving a cross-chain authenticable message refers to receiving the authenticatable message from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, the relay is further connected to at least one of other blockchain networks, the at least one of other blockchain networks includes a first blockchain network, the second blockchain network pre-stores a public key of the relay, and the device is disposed in the second blockchain network and includes: a receiving unit, configured to receive the authenticatable message and the digital signature of the authenticatable message from the relay, where the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; a verification unit, configured to verify the digital signature by using the public key of the relay; and a providing unit, configured to: after the verification succeeds, provide the authenticatable message to the second account based on the second account in the authenticatable message.

Another aspect of the present specification provides a computer readable storage medium, where the medium stores a computer program, and when the computer program is executed on a computer, the computer is enabled to perform any one of the previous methods.

Another aspect of the present specification provides a computing device, including a memory and a processor, where the memory stores executable code, and when the processor executes the executable code, any one of the previous methods is implemented.

According to an abstract blockchain interoperation model in the cross-chain solution provided in the implementations of the present specification, an authenticatable message is designed, so that a message sent from a blockchain network can be verified by another blockchain network to determine a specific blockchain network from which the message is sent and a specific identity entity (account number/contract) from which the message is sent. As such, based on the authenticatable message, cross-chain applications (contracts) can be programmed, so that developers can develop various cross-chain services and applications more easily.

BRIEF DESCRIPTION OF DRAWINGS

To make the implementations of the present specification clearer, the following describes the implementations of the present specification with reference to the accompanying drawings.

FIG. 1 is a schematic diagram illustrating a cross-chain system, according to an implementation of the present specification;

FIG. 2 is a flowchart illustrating a method for sending a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 3 is a schematic diagram illustrating a log generated after execution of a first smart contract;

FIG. 4 is a schematic diagram illustrating a pre-determined protocol stack, according to an implementation of the present specification;

FIG. 5 is a schematic diagram illustrating a form of an authenticatable message;

FIG. 6 is a schematic diagram illustrating a high-adaptability protocol stack, according to an implementation of the present specification;

FIG. 7 is a flowchart illustrating a method for relaying a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 8 is a flowchart illustrating a method for receiving a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 9 is a flowchart illustrating a method for relaying a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 10 is a flowchart illustrating a method for receiving a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 11 is a schematic diagram illustrating a device 1100 for sending a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 12 is a schematic diagram illustrating a device 1200 for relaying a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 13 is a schematic diagram illustrating a device 1300 for receiving a cross-chain authenticatable message, according to an implementation of the present specification;

FIG. 14 is a schematic diagram illustrating a device 1400 for relaying a cross-chain authenticatable message, according to an implementation of the present specification; and

FIG. 15 is a schematic diagram illustrating a device 1500 for receiving a cross-chain authenticatable message, according to an implementation of the present specification.

DESCRIPTION OF IMPLEMENTATIONS

The following describes the implementations of the present specification with reference to the accompanying drawings.

FIG. 1 is a schematic diagram illustrating a cross-chain system, according to an implementation of the present specification. As shown in FIG. 1, the cross-chain system includes a first blockchain network 11, a relay 12, and a second blockchain network 13. For example, the first blockchain network 11 includes account A, and the second blockchain network 13 includes account B, where both account A and account B can be user accounts or contract accounts. When account A in the first blockchain network needs to send information to account B in the second blockchain network, account A can send the information as an authenticatable message (AM). The authenticatable message is included in first data (data 1) on which consensus processing is performed and that is stored by account A into a blockchain network. the second blockchain network 13 can include a plurality of simplified payment verification (SPV) nodes, and the SPV nodes locally pre-obtain second data (data 2) in the first blockchain network 11, and data 2 is used to verify data 1. Each SPV node can obtain the first data (data 1) and location information of the first data (location 1) through the relay 12 between the first blockchain network 11 and the second blockchain network 13, and use data 2 to verify data 1, and provides the AM in data 1 to account B after the verification succeeds. Then, account B can perform service processing based on the AM.

It can be understood that the previous description with reference to FIG. 1 is only an example, but is not intended to limit the implementations of the present specification. For example, after obtaining data 1, the relay can verify data 1 based on the pre-obtained data 2 in the first blockchain network, add a digital signature on data 1, and then sends data 1 and the digital signature to the second blockchain network; and the second blockchain network can verify the digital signature based on a public key of a relay blockchain network, to verify data 1. The following describes the previous process in detail.

FIG. 2 is a flowchart illustrating a method for sending a cross-chain authenticatable message, according to an implementation of the present specification. Cross-chain sending refers to sending from a first account in a first blockchain network to another blockchain network, the first blockchain network is connected to the relay, the relay is further connected to at least one of other blockchain networks, and the at least one of other blockchain networks includes a second blockchain network. The method is performed by the first blockchain network and includes:

Step S202: Store first data through consensus into the first blockchain network by using the first account, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account.

Step S204: Provide the first data and first location information to the relay, to provide the authenticatable message to the second account in the second blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

In this implementation of the present specification, the first blockchain network and the second blockchain network can be any blockchain network, for example, bitcoin blockchain network or Ethereum blockchain network. The bitcoin blockchain network and Ethereum blockchain network send messages through an authenticatable message with a unified format. Therefore, this implementation of the present specification does not impose a limitation on a blockchain network type and a specific application scenario. The relay is an intermediate component between the first blockchain network and the second blockchain network. The blockchain network can be in a plurality of forms. For example, the relay can be a node in the first blockchain network and the second blockchain network, that is, the relay has an account in the first blockchain network and an account in the second blockchain network; or the relay is an intermediary device between the first blockchain network and the second blockchain network, which only transfers data but does not verify the data; or the relay is a trusted node, which verifies data received from the first blockchain network, and after the verification succeeds, sends the data to the second blockchain network; or the relay can be a verification blockchain network, which performs consensus verification on the data received from the first blockchain network, and then sends the data to the second blockchain network.

In step S202, the first data through consensus is stored into the first blockchain network by using the first account, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account.

The first account can be a user account or a contract account. The first data can be any one of the following types of data in a blockchain network: transaction, receipt, state of a state tree, smart contract memory, and relational database. Such data is stored into the blockchain network after being provided with consensus processing by corresponding nodes. Therefore, the data is consistent and authenticatable on each node. A person skilled in the art understands that a transaction can be sent in the blockchain network, and the previous data through consensus can be stored into the blockchain network. The process is not described in detail here for simplicity.

In an implementation, storing first data through consensus into the first blockchain network by using the first account includes: storing the first data into the first blockchain network by invoking a first smart contract by using the first account, where at least the following parameters are input to the first smart contract when the first smart contract is invoked by using the first account: an identifier of the second blockchain network, a second account, and message content. In an implementation, the first account is a contract account of a second smart contract. For example, the first account transfers parameters to a third smart contract in the second blockchain network by invoking the first smart contract, to implement cross-chain invoking of the third smart contract. The first smart contract is a specific smart contract used to store the first data into the first blockchain network to transfer a cross-chain authenticatable message. For example, the first smart contract can be invoked as a contract used for sending a message (that is, the second smart contract), and when the first smart contract is invoked, at least a receiving blockchain identifier (that is, the identifier of the second blockchain network), a receiving account (that is, the second account), and message content need to be input.

For example, when the first smart contract is being executed, a saving function “Save ( )” is included, and parameters input for the function are parameters inputted to the first smart contract, that is, the identifier of the second blockchain network, the second account, and the message content. In addition, the saving function obtains an account of the second smart contract that initiates the invocation (that is, the first account), combines the first account, a pre-determined identifier of the first blockchain network, and the input parameters (that is, the identifier of the second blockchain network, the second account, and the message content) into an authenticatable message in a pre-determined format (that is, a pre-determined protocol), and outputs the authenticatable message as a result of the function.

The result of the function is saved in a corresponding log. The log is included in a transaction receipt of a transaction corresponding to the invocation. After nodes in the first blockchain network perform consensus processing on the transaction receipt, the transaction receipt is stored into a block in the first blockchain network. That is, in this implementation, the first data is the receipt in the blockchain network, and a specific log in the receipt includes the authenticatable message. For example, in a block in the blockchain network, the receipt can be queried by using a contract identifier of the first smart contract as a pre-determined label. In an implementation, a specific topic (name) is specified in the log as a pre-determined label, which can be used to query the log subsequently. It can be understood that when the first data is a receipt, the first data needs to be labeled with the pre-determined label, so that the data can be queried subsequently. However, the first data is not limited to a receipt. For example, the first data can be data stored in a memory in which a smart contract is stored, or can be data stored in a relational database. In this case, the pre-determined label does not need to be labeled, and the first data can be directly obtained from a specific database (or memory).

For example, after the first smart contract is executed after being invoked based on the second smart contract for execution, a log shown in FIG. 3 is generated. FIG. 3 is a schematic diagram illustrating the log generated after execution of the first smart contract. As shown in FIG. 3, the log includes a pre-determined topic. For example, the topic can be “AM”, which is used to indicate whether the log is a log for sending an AM message from a blockchain network to the outside. The log includes the following fields: “To”, “From”, and “Data”. The “To” field corresponds to an account of an invoked contract, that is, an account of the first smart contract. The “From” field corresponds to an account that invokes a contract, that is, an account of the second smart contract (that is, the first account”. The “Data” field indicates an authenticatable message that needs to be sent for the second smart contract.

The authenticatable message satisfies the pre-determined protocol. FIG. 4 is a schematic diagram illustrating a pre-determined protocol stack, according to an implementation of the present specification. As shown in FIG. 4, the lowest layer is the first-layer protocol according to an implementation of the present specification. The first-layer protocol includes a sending blockchain identifier field (S_C_ID) and a second-layer protocol. The middle layer is a second-layer protocol, and the second-layer protocol includes a sending account field (S_A_id) and a third-layer protocol. The highest layer is the third-layer protocol, and the third-layer protocol includes a receiving blockchain identifier field (R_C_ID), a receiving account field (R_A_id), and a message content field. It can be understood that the sending account should be an account in a sending blockchain network, and the receiving account should be an account in a receiving blockchain network.

For example, as described above, the authenticatable message is a message that is sent from a first account in the first blockchain network to a second account in the second blockchain network. Assuming that the blockchain identifier of the first blockchain network is ID1, the first account is id1, the blockchain identifier of the second blockchain network is ID2, and the second account is id2. FIG. 5 illustrates a form of an authenticatable message. As shown in FIG. 5, based on the protocol stack shown in FIG. 4, the first-layer protocol includes ID1 and the second-layer protocol, the second-layer protocol includes id1 and the third-layer protocol, and the third-layer protocol includes ID2, id2, and message content.

The protocol stack is designed based on a verification process of the authenticatable message. The first-layer protocol and the second-layer protocol respectively correspond to a verification process of the sending blockchain network and a verification process of the sending account, and the third-layer protocol corresponds to a specific communication process and service processing process. The verification process and the communication process are described in detail below. With such a protocol stack, after the authenticatable message is received, layered verification can be performed on the authenticatable message, and after the verification succeeds, message content can be obtained, and specific service processing can be performed. Therefore, the protocol at each layer has specific verification semantics for layered verification.

In an implementation, the first-layer protocol further includes a protocol version number field and a reserved field. As such, the protocol stack can be upgraded and extended. The reserved field is an empty field.

In an implementation, the second-layer protocol further includes a type field used to indicate a usage scenario type of the authenticatable message. As such, the protocol stack can be used in a stackable manner in different usage scenarios. For example, for different usage scenarios (that is, different types of authenticatable messages), the message content field can correspond to different content, different formats, etc. For example, the scenario type is any one of the following types: message type, remote procedure call type, issuance/subscription type, and account transfer.

In an implementation, the third-layer protocol further includes a sequence number field used to indicate a current sending sequence number when the authenticatable message is sent to the second account for a plurality of times by using the first account.

Field values of the protocol version number field, the reserved field, the type field, and the sequence number field can be input, in a similar way, to the first smart contract as input parameters when the first smart contract is invoked by the first account, so that the saving function in the first smart contract can output, based on these input parameters, an authenticatable message including the field values.

FIG. 6 is a schematic diagram illustrating a high-adaptability protocol stack, according to an implementation of the present specification. As shown in FIG. 6, compared with the layers in the protocol stack shown in FIG. 4, the first-layer protocol in this protocol stack further includes a version number field and a reserved field, the second-layer protocol in this protocol stack further includes a type field, and the third-layer protocol in this protocol stack further includes a sequence number field. As described above, this protocol stack can be upgraded and extended, can be used in a plurality of types of scenarios, and can be used for communication for multiple times, and therefore has high adaptability.

The previous has described a process in which data through consensus is stored into the first blockchain network based on an example in which the first smart contract is invoked by the second smart contract. However, the implementations of the present specification are not limited thereto. For example, the first account is a user account, and the first account sends a transaction to any one of other accounts, to store first data to a blockchain network. For example, the first data can alternatively be transaction data in a block. For example, a pre-determined label can be specified in a data field of the transaction, to indicate that the transaction is used for sending a cross-chain message, and the data field of the transaction includes the previous authenticatable message. As such, after the first account sends the transaction, and after consensus verification is performed on the transaction, the transaction is stored in to a block. In a subsequent process, the transaction data can be found based on the pre-determined label, and the authenticatable message is obtained from the transaction data.

In step S204, the first data and first location information are provided to the relay, to provide the authenticatable message to the second account in the second blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

As described above, in this implementation of the present specification, different types of relays can be used, and the first data can be provided to the relay by using different methods based on different implementations of the relay. For example, the relay is a node in the first blockchain network and the second blockchain network, so that the relay can obtain the first data locally (for example, a block or a state tree), and obtain the first location data. The first location data indicates a location of the first data in a blockchain network; for example, when the first data is a receipt, the first location data includes a number of a block in which the receipt is located and a number of the receipt in the block. For example, the relay is a transition device connected to both the first blockchain network and the second blockchain network, so that any node in the first blockchain network can locally obtain the first data and location information of the first data based on a request of the relay, and send the first data and location information of the first data to the relay. After obtaining the first data and location information of the first data, the relay can perform different steps based on a form of the relay, to provide an authenticatable message in the first data to the second account in the second blockchain network. The process is described in detail below.

FIG. 7 is a flowchart illustrating a method for relaying a cross-chain authenticatable message, according to an implementation of the present specification. The method is performed by a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, and the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account. The method includes:

Step S702: Obtain the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

Step S704: Send, based on the identifier of the second blockchain network in the authenticatable message, the first data and the first location information to the second blockchain network.

After the method shown in FIG. 2 is performed on the first blockchain network, the first data through consensus is stored into the first blockchain network, so that this method can be implemented.

This method is performed by the relay. The steps for performing this method vary with specific implementations of the relay. In this method, for example, the relay is a relay between the first blockchain network and the second blockchain network, that is, the relay only transfers data but does not verify the data, which means that the relay is not responsible for authenticity and integrity of the data.

In step S702, the first data and the first location information are obtained from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

In an implementation, the first data with a pre-determined label is stored into a blockchain network, where the pre-determined label is used to query cross-chain data to be sent. For example, the pre-determined label is an account of the first smart contract, and another contract account needs to invoke the first smart contract during transfer of cross-chain information. After the first smart contract is invoked, a corresponding receipt includes the account of the first smart contract. As such, the data can be queried from a blockchain network based on the account of the first smart contract, and the obtained data can be used as the first data, and the identifier of the block in which the data and the number of the receipt in the block can be determined and used as the first location information. For example, the relay can subscribe to any node for a receipt with the account of the first smart contract, to receive the first data and the first location information from the node. As described above, when the first data is specific data, the first data and a storage location of the first data can be obtained from a specific database or memory.

In step S704, the first data and the first location information are sent to the second blockchain network based on the identifier of the second blockchain network in the authenticatable message.

As described above, after receiving the first data and the first location information (for example, the first data is the receipt of the invoked first smart contract), the relay finds a specific log from the receipt based on the account of the first smart contract or a pre-determined topic of a log, and obtains an authenticatable message from a data field in the specific log. Based on the pre-determined protocol, it can be determined that the identifier of the second blockchain network in the authenticatable message is an identifier of a blockchain network that is to receive the authenticatable message, so that the first data and the first location information can be sent to the second blockchain network. It can be understood that it is possible that the relay is connected to more than two blockchain networks, for example, it is possible that the relay is further connected to a third blockchain network and a fourth blockchain network. As such, a process in which the relay sends data based on the identifier of the second blockchain network after receiving the first data and the first location information is a process in which the relay addresses a receiving blockchain network based on a receiving blockchain identifier.

FIG. 8 is a flowchart illustrating a method for receiving a cross-chain authenticatable message, according to an implementation of the present specification. Cross-chain receiving refers to receiving from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, at least one piece of second data that is related to at least one of other blockchain networks is synchronized to the second blockchain network by using the relay, and the at least one of other blockchain networks includes a first blockchain network. The method is performed by the second blockchain network and includes:

Step S802: Receive first data and first location information from the relay, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account, and the first location information indicates a location of the first data in the first blockchain network.

Step S804: Obtain, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network.

Step S806: Verify the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information.

Step S808: After the verification succeeds, provide the authenticatable message to the second account based on the second account in the authenticatable message.

The relay in the method shown in FIG. 8 corresponds to the relay in the method shown in FIG. 7. The method shown in FIG. 8 can be performed after the method shown in FIG. 7 is performed. For example, a plurality of verification nodes in the second blockchain network verify an authenticatable message, and second data related to each of other blockchain networks is synchronized to the verification nodes through the relay, where the second data is used to verify the authenticatable message. The verification node and the second data vary with the verification method. For example, when verification is performed by using a simplified payment verification (SPV) method, the verification node is an SPV node, and the second data is a block head of each block in a corresponding blockchain network.

First, in step S802, first data and first location information are received from the relay, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account, and the first location information indicates a location of the first data in the first blockchain network.

As described above, the first data can be, for example, a receipt with a pre-determined label that is obtained by the relay from a block in the first blockchain network. After receiving the receipt and a location of the receipt, the relay can transfer the receipt and the location of the receipt to the second blockchain network, so that each node in the second blockchain network can obtain the receipt and the location of the receipt, so that an account node or a verification node in the second blockchain network can perform steps S804-S808.

In step S804, the second data related to the first blockchain network is obtained based on the identifier of the first blockchain network in the authenticatable message.

As described above, the protocol stack shown in FIG. 4 is a layered protocol stack based on a verification process, and the first-layer protocol is used for the verification process of the sending blockchain identifier. As such, first the second data corresponding to the first blockchain network can be obtained from the locally stored second data based on the sending blockchain identifier (that is, the identifier of the first blockchain network) in the first-layer protocol. Because of the layered design of the protocol stack, when this step is performed, only the sending blockchain identifier field of the first-layer protocol needs to be read, and specific content of the second-layer protocol included in the first-layer protocol does not need to be read.

In step S806, the authenticatable message is verified based on the first data, the second data related to the first blockchain network, and the first location information.

In an implementation, the first data is a first receipt in a first block in the first blockchain network, the first location information includes a block number of the first block and a receipt number of the first receipt in the first block, and the second data related to the first blockchain network includes a block head of each block in the first blockchain network. Verifying the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information includes: verifying the sending blockchain identifier of the first-layer protocol in the authenticatable message. Verifying the sending blockchain identifier includes: using a simplified payment verification (SPV) method to verify, based on the first receipt, the block head of each block, and a Merkle tree path that is associated with the first receipt and that is included in the first block, that the first receipt is received from the first block in the first blockchain network, where the Merkle tree path is obtained based on the first location information. The SPV method includes the following steps:

Calculating a receipt hash value of the first receipt.

Calculating a root hash value of the Merkle tree based on the Merkle tree path.

Comparing the root hash value and a root hash value of a receipt in a block head of the first block, to determine whether the first receipt is in the first block.

In an implementation, the SPV verification can further include: after determining that the first receipt is in the first block, verifying, based on the location of the first block, whether the block head of the block is included in a known longest blockchain network, to determine whether consensus processing has been performed on the first block. In an implementation, the blockchain identifier corresponds to a head hash value of a genesis block in the blockchain network, and the SPV verification can further include: verifying, based on the head hash value and the parent hash value in the block head of the first block and the block head of each block, whether the head hash value of the genesis block in the blockchain network corresponds to a blockchain identifier of the first blockchain network.

In an implementation, with reference to the descriptions about FIG. 4, based on a receipt that includes the log shown in FIG. 4 and that is automatically generated after the second smart contract invokes the first smart contract, the first receipt can prove that the first account in the authenticatable message is an account used to send the message.

In an implementation, the first receipt is stored into the blockchain network when a user account (that is, the first account) sends a transaction, and the authenticatable message is input to the transaction data by a user. After the first receipt is generated, the authenticatable message is included in a first log of the first receipt; and in this case, the verification further includes verifying the sending account in the second-layer protocol in the authenticatable message, specifically, verification can be performed based on a sending field in the first log, to determine whether the first account is an account used to send the authenticatable message.

In step S808, after the verification succeeds, the authenticatable message is provided to the second account based on the second account in the authenticatable message.

In an implementation, as described above, the second smart contract in the first blockchain network invokes the first smart contract to transfer information to the third smart contract in the second blockchain network, to invoke the third smart contract. In this case, the second account is a contract account of the third smart contract, and the authenticatable message is, for example, a parameter input to the third smart contract. In an implementation, providing the authenticatable message to the second account includes: invoking the third smart contract by using the authenticatable message as an input parameter, to provide the authenticatable message to the second account. After the third smart contract is invoked, a specific service process is performed based on the third-layer protocol in the authenticatable message. It can be understood that the second account is not limited to an account of a smart contract. For example, the second account can alternatively be a user account; and in this case, the authenticatable message is provided to the user account by a verification node by using a common blockchain method (for example, sending a transaction).

FIG. 9 is a flowchart illustrating a method for relaying a cross-chain authenticatable message, according to an implementation of the present specification. The method is performed by a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, and the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account. The method includes:

Step S902: Obtain the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

Step S904: Obtain, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network.

Step S906: Verify the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information.

Step S908: When the verification succeeds, add a digital signature on the authenticatable message.

Step S910: Send, based on the identifier of the second blockchain network in the authenticatable message, the first data and a digital signature of the first data to the second blockchain network.

In this method, the relay is a trusted node or a verification blockchain network. After obtaining first data from a first blockchain network, the relay can locally verify the first data. After the verification succeeds, the relay can add a digital signature on the first data, and send the first data and the digital signature to the second blockchain network, so that the second blockchain network can verify the first data based on the digital signature of the relay, thereby simplifying the verification process of the second blockchain network. Steps S902 and S910 in this method correspond to steps S702 and

S704 described above. For details about steps S904 and S906, references can be made to the descriptions about steps S804 and S806. Details are omitted here for simplicity.

FIG. 10 is a flowchart illustrating a method for receiving a cross-chain authenticatable message, according to an implementation of the present specification. Cross-chain receiving refers to receiving from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, the relay is further connected to at least one of other blockchain networks, the at least one of other blockchain networks includes a first blockchain network, and the second blockchain network pre-stores a public key of the relay. The method is performed by the second blockchain network and includes:

Step S1002: Receive an authenticatable message and a digital signature of the authenticatable message from the relay, where the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account.

Step S1004: Verify the digital signature by using the public key of the relay.

Step S1006: After the verification succeeds, provide the authenticatable message to the second account based on the second account in the authenticatable message.

The relay in the method shown in FIG. 10 corresponds to the relay in the method shown in FIG. 9. The method shown in FIG. 10 can be performed after the method shown in FIG. 9 is performed. The method can be performed by any node or client in the second blockchain network. The node (or client) needs to store only a public key of the relay, and then can verify an authenticatable message. As such, the solution shown in FIG. 8 is not needed, in which the first data needs to be received from the relay. Instead, only the authenticatable message needs to be received. For details about step S1006, references can be made to the description about step S808. Details are omitted here for simplicity.

FIG. 11 is a schematic diagram illustrating a device 1100 for sending a cross-chain authenticatable message, according to an implementation of the present specification. Cross-chain sending refers to sending from a first account in a first blockchain network to another blockchain network, the first blockchain network is connected to the relay, the relay is further connected to at least one of other blockchain networks, and the at least one of other blockchain networks includes a second blockchain network. The device is disposed in the first blockchain network and includes: a storing unit 111, configured to store first data through consensus into the first blockchain network by using the first account, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; and a providing unit 112, configured to provide the first data and first location information to the relay, to provide the authenticatable message to the second account in the second blockchain network, where the first location information indicates a location of the first data in the first blockchain network.

In an implementation, the storing unit 111 is further configured to store the first data into the first blockchain network by invoking a first smart contract by using the first account, where at least the following parameters are input to the first smart contract when the first smart contract is invoked by using the first account: the identifier of the second blockchain network, the second account, and message content.

FIG. 12 is a schematic diagram illustrating a device 1200 for relaying a cross-chain authenticatable message, according to an implementation of the present specification. The device is disposed at a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account. The device includes: an acquisition unit 121, configured to obtain the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network; and a sending unit 122, configured to send, based on the identifier of the second blockchain network in the authenticatable message, the first data and the first location information to the second blockchain network.

In an implementation, the first data is labeled with a pre-determined label, and the acquisition unit is further configured to obtain the first data and the first location information from the first blockchain network based on the pre-determined label.

FIG. 13 is a schematic diagram illustrating a device 1300 for receiving a cross-chain authenticatable message, according to an implementation of the present specification. Cross-chain receiving refers to receiving from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, at least one piece of second data that is related to at least one of other blockchain networks is synchronized to the second blockchain network by using the relay, and the at least one of other blockchain networks includes a first blockchain network. The device is disposed in the second blockchain network and includes: a receiving unit 131, configured to receive first data and first location information from the relay, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account, and the first location information indicates a location of the first data in the first blockchain network; an acquisition unit 132, configured to obtain, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network; a verification unit 133, configured to verify the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information; and a providing unit 134, configured to: after the verification succeeds, provide the authenticatable message to the second account based on the second account in the authenticatable message.

In an implementation, the first data is a first receipt in a first block in the first blockchain network, the first location information includes a block number of the first block and a receipt number of the first receipt in the first block, the second data related to the first blockchain network includes a block head of each block in the first blockchain network, and the verification unit 133 is further configured to use a simplified payment verification method to verify, based on the first receipt, the block head of each block, and a Merkle tree path that is associated with the first receipt and that is included in the first block, that the first receipt is received from the first block in the first blockchain network, where the Merkle tree path is obtained based on the first location information.

In an implementation, after the first data is generated, the authenticatable message is included in a first log of the first receipt, and the verification unit 133 is further configured to verify, based on a sending field in the first log, that the first account is an account used to send the authenticatable message.

In an implementation, the second account is a contract account of a third smart contract, and the providing unit 134 is further configured to invoke the third smart contract by using the authenticatable message as an input parameter, to provide the authenticatable message to the second account.

FIG. 14 illustrates a device 1400 for relaying a cross-chain authenticatable message, according to an implementation of the present invention. The device is disposed at a relay, the relay is connected to at least two blockchain networks, and the at least two blockchain networks include a first block chain and a second blockchain network, and the first blockchain network pre-stores first data through consensus, where the first data includes an authenticatable message, the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, and the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second ledge. The device includes: a first acquisition unit 141, configured to obtain the first data and first location information from the first blockchain network, where the first location information indicates a location of the first data in the first blockchain network; and a second acquisition unit 142, configured to obtain, based on the identifier of the first blockchain network in the authenticatable message, second data related to the first blockchain network; a verification unit 143, configured to verify the authenticatable message based on the first data, the second data related to the first blockchain network, and the first location information; and a signing unit 144, configured to: when the verification succeeds, add a digital signature on the authenticatable message; and a sending unit 145, configured to send, based on the identifier of the second blockchain network in the authenticatable message, the first data and a digital signature of the first data to the second blockchain network.

FIG. 15 illustrates a device 1500 for receiving a cross-chain authenticatable message, according to an implementation of the present invention. Cross-chain receiving refers to receiving from another blockchain network by a second account in a second blockchain network, the second blockchain network is connected to a relay, the relay is further connected to at least one of other blockchain networks, the at least one of other blockchain networks includes a first blockchain network, the second blockchain network pre-stores a public key of the relay. The device is disposed in the second blockchain network and includes: a receiving unit 151, configured to receive the authenticatable message and the digital signature of the authenticatable message from the relay, where the authenticatable message satisfies a pre-determined protocol stack, the pre-determined protocol stack includes a first-layer protocol to a third-layer protocol from outside to inside, the first-layer protocol includes a sending blockchain identifier field and a second-layer protocol, the second-layer protocol includes a sending account and a third-layer protocol, the third-layer protocol includes a receiving blockchain identifier field, a receiving account field, and a message content field, where the sending blockchain identifier field, the sending account field, the receiving blockchain identifier field, and the receiving account field respectively correspond to the following field values: an identifier of the first blockchain network, the first account, an identifier of the second blockchain network, and a second account; a verification unit 152, configured to verify the digital signature by using the public key of the relay; and a providing unit 153, configured to: after the verification succeeds, provide the authenticatable message to the second account based on the second account in the authenticatable message.

Another aspect of the present specification provides a computer readable storage medium, where the medium stores a computer program, and when the computer program is executed on a computer, the computer is enabled to perform any one of the previous methods.

Another aspect of the present specification provides a computing device, including a memory and a processor, where the memory stores executable code, and when the processor executes the executable code, any one of the previous methods is implemented.

According to an abstract blockchain interoperation model in the cross-chain solution provided in the implementations of the present specification, an authenticatable message is designed, so that a message sent from a blockchain network can be verified by another blockchain network to determine a specific blockchain network from which the message is sent and a specific identity entity (account number/contract) from which the message is sent. As such, based on the authenticatable message, cross-chain applications (contracts) can be programmed, so that developers can develop various cross-chain services and applications more easily. In addition, the authenticatable is highly extensible and supports protocol stacking, so that various cross-chain interoperation technologies and application scenarios can be standardized. Further, the authenticatable message can be implemented on a heterogeneous platform, so that the blockchain network can be easily upgraded to access multiple cross-chain platforms and connect to a plurality of blockchain networks.

It should be understood that terms such as “first” and “second”in the present specification are only used to distinguish between similar concepts for ease of description, and does not impose any other limitation.

It is worthwhile to note that the implementations of the present specification are described in a progressive way. For same or similar parts of the implementations, mutual references can be made to the implementations. Each implementation focuses on a difference from the other implementations. Particularly, a system implementation is basically similar to a method implementation, and therefore is described briefly. For related parts, references can be made to related descriptions in the method implementation.

Specific implementations of the present specification are described above. Other implementations fall within the scope of the appended claims. In some situations, the actions or steps described in the claims can be performed in an order different from the order in the implementation and the desired results can still be achieved. In addition, the process depicted in the accompanying drawings does not necessarily require a particular execution order to achieve the desired results. In some implementations, multi-tasking and parallel processing can be advantageous.

A person of ordinary skill in the art can be further aware that, in combination with the examples described in the implementations disclosed in the present specification, units and algorithm steps can be implemented by electronic hardware, computer software, or a combination thereof. To clearly describe the interchangeability between the hardware and the software, the previous has generally described compositions and steps of each example according to functions. Whether the functions are performed by hardware or software depends on particular applications and design constraint conditions of the technical solutions. A person of ordinary skill the art can use different methods to implement the described functions for each particular application, but it should not be considered that the implementation goes beyond the scope of the present disclosure.

In combination with the implementations disclosed in the present specification, method or algorithm steps can be implemented by hardware, a software module executed by a processor, or a combination thereof. The software module can reside in a random access memory (RAM), a memory, a read-only memory (ROM), an electrically programmable ROM, an electrically erasable programmable ROM, a register, a hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

The objectives, technical solutions, and benefits of the present disclosure are further described in detail in the previous specific implementations. It should be understood that the previous descriptions are merely specific implementations of the present disclosure, but are not intended to limit the protection scope of the present disclosure. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present disclosure shall fall within the protection scope of the present disclosure. 

1. A computer-implemented method for sending cross-chain messages comprising: storing, through consensus of blockchain nodes of a first blockchain network, an authenticatable message (AM) associated with a first account from which the AM is to be sent, to a blockchain associated with the first blockchain network, wherein the AM is generated based on a protocol stack comprising an outer-layer protocol, a middle-layer protocol, and an inner-layer protocol, wherein the outer-layer protocol comprises an identifier of the first blockchain network and the middle-layer protocol, the middle-layer protocol comprises information of the first account and the inner-layer protocol, and the inner-layer protocol comprises an identifier of a second blockchain network, information of a second account to which the AM is to be sent and that is associated with the second blockchain network, and message content of the AM; and transmitting the AM and location information to a relay to be forwarded to the second blockchain network for layered verification of the AM by the second blockchain network, wherein the location layered verification comprises: obtaining local data related to the first blockchain network, based on the identifier of the first blockchain network; using the obtained local data related to the first blockchain network and the location information that identifies a location of the AM in the first blockchain network to verify the AM, wherein the outer-layer protocol is used to verify the identifier of the first blockchain network, and the middle-layer protocol is used to verify the first account; and after verification of the AM succeeds, using the inner-layer protocol to provide the message content to the second account.
 2. The method according to claim 1, wherein storing the AM associated with the first account to the blockchain associated with the first blockchain network is performed based on executing a smart contract invoked through the first account, and wherein the identifier of the second blockchain network, the information of the second account, and the message content of the AM are provided by the first account as input to invoke the smart contract.
 3. The method according to claim 2, wherein the AM and a corresponding label is included in a data field of a blockchain transaction, and wherein the corresponding label identifies the blockchain transaction and that the blockchain transaction is a cross-chain transaction performed between the first account and an account outside of the first blockchain network.
 4. The method according to claim 3, wherein the AM is included in a data field of a log generated based on executing the smart contract.
 5. The method according to claim 4, wherein the log is associated with the corresponding label, wherein the corresponding label indicates that the log corresponds to the AM that is transmitted outside of the first blockchain network.
 6. The method according to claim 4, wherein the corresponding label is an account identifier associated with the smart contract.
 7. The method according to claim 1, wherein the outer-layer protocol further comprises a version number of the protocol stack and a reserved field.
 8. The method according to claim 1, wherein the middle-layer protocol further comprises a type field indicating a type of usage scenario of the AM.
 9. The method according to claim 8, wherein the type of usage scenario is one of messaging, remote procedure call, issuance, and subscription.
 10. The method according to claim 1, wherein the inner-layer protocol further comprises a sequence number indicating a relative time-sequence of the AM in a sequence of AMs sent to the second account.
 11. The method according to claim 2, wherein the smart contract is a first smart contract, and the first account is a contract account associated with a second smart contract.
 12. A computer-implemented system, comprising: one or more computers; and one or more computer memory devices interoperably coupled with the one or more computers and having tangible, non-transitory, machine-readable media storing one or more instructions that, when executed by the one or more computers, perform operations comprising: storing, through consensus of blockchain nodes of a first blockchain network, an authenticatable message (AM) associated with a first account from which the AM is to be sent, to a blockchain associated with the first blockchain network, wherein the AM is generated based on a protocol stack comprising an outer-layer protocol, a middle-layer protocol, and an inner-layer protocol, wherein the outer-layer protocol comprises an identifier of the first blockchain network and the middle-layer protocol, the middle-layer protocol comprises information of the first account and the inner-layer protocol, and the inner-layer protocol comprises an identifier of a second blockchain network, information of a second account to which the AM is to be sent and that is associated with the second blockchain network, and message content of the AM; and transmitting the AM and location information to a relay to be forwarded to the second blockchain network for layered verification of the AM by the second blockchain network, wherein the layered verification comprises: obtaining local data related to the first blockchain network, based on the identifier of the first blockchain network; using the obtained local data related to the first blockchain network and the location information that identifies a location of the AM in the first blockchain network to verify the AM, wherein the outer-layer protocol is used to verify the identifier of the first blockchain network, and the middle-layer protocol is used to verify the first account; and after verification of the AM succeeds, using the inner-layer protocol to provide the message content to the second account.
 13. The computer-implemented system according to claim 12, wherein storing the AM associated with the first account to the blockchain associated with the first blockchain network is performed based on executing a smart contract invoked through the first account, and wherein the identifier of the second blockchain network, the information of the second account, and the message content of the AM are provided by the first account as input to invoke the smart contract.
 14. The computer-implemented system according to claim 13, wherein the AM and a corresponding label is included in a data field of a blockchain transaction, and wherein the corresponding label identifies the blockchain transaction and that the blockchain transaction is a cross-chain transaction performed between the first account and an account outside of the first blockchain network.
 15. The computer-implemented system according to claim 14, wherein the AM is included in a data field of a log generated based on executing the smart contract.
 16. The computer-implemented system according to claim 15, wherein the log is associated with the corresponding label, wherein the corresponding label indicates that the log corresponds to the AM that is transmitted outside of the first blockchain network.
 17. The computer-implemented system according to claim 15, wherein the corresponding label is an account identifier associated with the smart contract.
 18. The computer-implemented system according to claim 12, wherein the outer-layer protocol further comprises a version number of the protocol stack and a reserved field.
 19. The computer-implemented system according to claim 12, wherein the middle-layer protocol further comprises a type field indicating a type of usage scenario of the AM.
 20. The computer-implemented system according to claim 19, wherein the type of usage scenario is one of messaging, remote procedure call, issuance, and subscription.
 21. The computer-implemented system according to claim 12, wherein the inner-layer protocol further comprises a sequence number indicating a relative time-sequence of the AM in a sequence of AMs sent to the second account.
 22. The computer-implemented system according to claim 13, wherein the smart contract is a first smart contract, and the first account is a contract account associated with a second smart contract.
 23. A non-transitory, computer-readable medium storing one or more instructions executable by a computer system to perform operations comprising: storing, through consensus of blockchain nodes of a first blockchain network, an authenticatable message (AM) associated with a first account from which the AM is to be sent, to a blockchain associated with the first blockchain network, wherein the AM is generated based on a protocol stack comprising an outer-layer protocol, a middle-layer protocol, and an inner-layer protocol, wherein the outer-layer protocol comprises an identifier of the first blockchain network and the middle-layer protocol, the middle-layer protocol comprises information of the first account and the inner-layer protocol, and the inner-layer protocol comprises an identifier of a second blockchain network, information of a second account to which the AM is to be sent and that is associated with the second blockchain network, and message content of the AM; and transmitting the AM and location information to a relay to be forwarded to the second blockchain network for layered verification of the AM by the second blockchain network, wherein the layered verification comprises: obtaining local data related to the first blockchain network, based on the identifier of the first blockchain network; using the obtained local data related to the first blockchain network and the location information that identifies a location of the AM in the first blockchain network to verify the AM, wherein the outer-layer protocol is used to verify the identifier of the first blockchain network, and the middle-layer protocol is used to verify the first account; and after verification of the AM succeeds, using the inner-layer protocol to provide the message content to the second account.
 24. The non-transitory, computer-readable medium of claim 23, wherein storing the AM associated with the first account to the blockchain associated with the first blockchain network is performed based on executing a smart contract invoked through the first account, and wherein the identifier of the second blockchain network, the information of the second account, and the message content of the AM are provided by the first account as input to invoke the smart contract.
 25. The non-transitory, computer-readable medium of claim 24, wherein the AM and a corresponding label is included in a data field of a blockchain transaction, and wherein the corresponding label identifies the blockchain transaction and that the blockchain transaction is a cross-chain transaction performed between the first account and an account outside of the first blockchain network.
 26. The non-transitory, computer-readable medium of claim 25, wherein the AM is included in a data field of a log generated based on executing the smart contract.
 27. The non-transitory, computer-readable medium of claim 26, wherein the log is associated with the corresponding label, wherein the corresponding label indicates that the log corresponds to the AM that is transmitted outside of the first blockchain network.
 28. The non-transitory, computer-readable medium of claim 26, wherein the corresponding label is an account identifier associated with the smart contract.
 29. The non-transitory, computer-readable medium of claim 23, wherein the outer-layer protocol further comprises a version number of the protocol stack and a reserved field.
 30. The non-transitory, computer-readable medium of claim 23, wherein the middle-layer protocol further comprises a type field indicating a type of usage scenario of the AM. 